Deck 7: Cellular Respiration and Fermentation

A)glucose → citric acid cycle → ATP → NAD⁺
B)glucose → NADH → electron transport chain → oxygen
C)glucose → pyruvate → acetyl CoA → ATP → oxygen
D)glucose → glycolysis → electron transport chain → NADH → ATP
E)glucose → glycolysis → citric acid cycle → NADH → ATP

A)electron transport
B)glycolysis
C)the citric acid cycle
D)oxidative phosphorylation
E)chemiosmosis

A)It gains electrons and gains potential energy.
B)It gains electrons and loses potential energy.
C)It loses electrons and loses potential energy.
D)It loses electrons and gains potential energy.

A)0%
B)2%
C)10%
D)38%
E)100%

A)hydrolyzed.
B)hydrogenated.
C)oxidized.
D)reduced.
E)an oxidizing agent.

A)oxidation of O₂ and reduction of H₂O
B)oxidation of C₆H₁₂O₆ and reduction of O₂
C)reduction of CO₂ and oxidation of O₂
D)reduction of C₆H₁₂O₆ and oxidation of CO₂

A)glycolysis
B)accepting electrons at the end of the electron transport chain
C)the citric acid cycle
D)the oxidation of pyruvate to acetyl CoA
E)the phosphorylation of ADP to form ATP

A)They have many oxygen atoms.
B)They have few nitrogen atoms.
C)They have a large number of electrons associated with hydrogen.
D)They have many carbon atoms bound together by single covalent bonds.

A)1
B)3
C)6
D)12
E)36

A)cytosol
B)outer mitochondrial membrane
C)inner mitochondrial membrane
D)mitochondrial matrix

A)NAD⁺ is the source of electrons used in oxidative phosphorylation.
B)NAD⁺ has more chemical energy than NADH.
C)NAD⁺ is oxidized by the action of dehydrogenase enzymes.
D)NAD⁺ is reduced to NADH during glycolysis.

A)chemiosmosis
B)electron transport
C)photophosphorylation
D)oxidative phosphorylation
E)substrate-level phosphorylation

A)dehydrogenated.
B)oxidized.
C)reduced.
D)redoxed.
E)hydrolyzed.

A)The electron loses potential energy.
B)The electron gains potential energy.
C)The electron gains kinetic energy.
D)The electron oxidizes the more electronegative atom.

A)0%
B)2%
C)10%
D)38%
E)100%

A)The more electronegative atom is reduced,and energy is released.
B)The more electronegative atom is reduced,and energy is consumed.
C)The more electronegative atom is oxidized,and energy is consumed.
D)The more electronegative atom is oxidized,and energy is released.

A)It gains electrons and gains potential energy.
B)It gains electrons and loses potential energy.
C)It loses electrons and loses potential energy.
D)It loses electrons and gains potential energy.

A)glucose → citric acid cycle → glycolysis → pyruvate oxidation → electron transport chain
B)glucose → pyruvate oxidation → glycolysis → electron transport chain → citric acid cycle
C)glucose → glycolysis → pyruvate oxidation → citric acid cycle → electron transport chain
D)glucose → glycolysis → citric acid cycle → pyruvate oxidation → electron transport chain
E)glucose → pyruvate oxidation → citric acid cycle → glycolysis → electron transport chain

A)chemiosmosis
B)electron transport
C)photophosphorylation
D)oxidative phosphorylation
E)substrate-level phosphorylation

A)transfer of electrons from organic molecules to acetyl CoA.
B)high-energy phosphate bonds from organic molecule intermediates in the citric acid cycle.
C)splitting water to produce oxygen.
D)a proton gradient across a membrane.

A)Most of the-free energy available from the oxidation of glucose is captured by the production of ATP.
B)Glycolysis is a very inefficient process,with much of the energy from glucose released as heat.
C)Most of the free energy available from the oxidation of glucose remains in pyruvate,one of the products of glycolysis.
D)Glycolysis consists of many enzyme-catalyzed reactions,each of which extracts a small amount of energy from the glucose molecule.

A)2 NAD⁺,2 pyruvate,and 2 ATP
B)4 NAD⁺,2 pyruvate,and 4 ADP
C)2 NAD⁺ and 4 ADP
D)2 NAD⁺ and 2 ADP
E)2 NADH and 2 ADP

A)1/6
B)1/3
C)1/2
D)2/3
E)all of it

A)It is stored in two ATP molecules.
B)It is released as heat.
C)It is retained in two pyruvate molecules.
D)It is stored in the two NADH molecules.

A)Two molecules of ATP are used,and two molecules of ATP are produced.
B)Two molecules of ATP are used,and four molecules of ATP are produced.
C)Four molecules of ATP are used,and two molecules of ATP are produced.
D)Two molecules of ATP are used,and six molecules of ATP are produced.

A)NAD⁺
B)NADH
C)ATP
D)FAD
E)FADH₂

A)glycolysis and the oxidation of pyruvate to acetyl CoA
B)oxidation of pyruvate to acetyl CoA and the citric acid cycle
C)the citric acid cycle and oxidative phosphorylation
D)glycolysis and the citric acid cycle

A)CO₂ and H₂O
B)CO₂ and pyruvate
C)NADH and pyruvate
D)CO₂ and NADH
E)H₂O,FADH₂,and citrate

A)an agent that reacts with oxygen and depletes its concentration in the cell
B)an agent that binds to pyruvate and inactivates it
C)an agent that closely mimics the structure of glucose but is not metabolized
D)an agent that reacts with NADH and oxidizes it to NAD⁺
E)an agent that blocks the passage of electrons along the electron transport chain

A)NAD⁺
B)NADH
C)ATP
D)FAD
E)FADH₂

A)to donate high energy electrons to the electron transport chain
B)to serve as an acceptor for released carbon,forming CO₂
C)to serve as an acceptor for electrons and protons,forming water
D)to donate high energy electrons to NAD⁺,forming NADH

A)cytosol
B)outer mitochondrial membrane
C)inner mitochondrial membrane
D)mitochondrial intermembrane space
E)mitochondrial matrix

A)4
B)5
C)6
D)10
E)12

A)2 NAD⁺,2 pyruvate,and 2 ATP
B)4 NADH,2 pyruvate,and 4 ATP
C)2 NADH,2 pyruvate,and 2 ATP
D)6 CO₂,2 NADH,2 pyruvate,and 2 ATP
E)6 CO₂,2 pyruvate,and 30 ATP

A)Early steps consume energy from ATP and NADH,and later steps store an equal amount of energy in ATP and NAD⁺.
B)Early steps consume energy from ATP and NADH,and later steps store an increased amount of energy in ATP and NADH.
C)Early steps consume energy from ATP and NADH,and later steps store an increased amount of energy in ATP.
D)Early steps consume energy from ATP,and later steps store an increased amount of energy in ATP and NADH.
E)Early steps consume energy from NADH,and later steps store an increased amount of energy in ATP and NADH.

A)2 NAD⁺,2 pyruvate,and 2 ATP
B)2 NADH,2 pyruvate,and 2 ATP
C)2 FADH₂,2 pyruvate,and 4 ATP
D)6 CO₂,2 pyruvate,and 2 ATP
E)6 CO₂,2 pyruvate,and 30 ATP

A)2
B)4
C)6
D)8
E)10

A)It has been reduced as a result of a redox reaction involving the loss of an inorganic phosphate.
B)It has a decreased chemical energy and is less likely to provide energy for cellular work.
C)It has been oxidized as a result of a redox reaction involving the gain of an inorganic phosphate.
D)It has increased chemical potential energy that may be used to do cellular work.

A)1/6
B)1/3
C)1/2
D)2/3
E)all of it

A)oxidation of glucose to CO₂ and water
B)the thermodynamically favorable flow of electrons from NADH to proteins associated with the mitochondrial electron transport chain
C)the transfer of protons and electrons to oxygen
D)the proton-motive force across the inner mitochondrial membrane
E)the thermodynamically favorable transfer of high-energy phosphate groups from molecules in glycolysis and the citric acid cycle to ADP

A)It increases the surface area for glycolysis.
B)It increases the surface area for the citric acid cycle.
C)It increases the surface area for oxidative phosphorylation.
D)It increases the surface area for substrate-level phosphorylation.

A)2
B)4
C)15
D)30-32
E)60-64

A)only mitochondria in animal cells
B)only bacteria that generate proton gradients across their plasma membranes
C)only mitochondria and chloroplasts
D)only mitochondria and bacteria that generate proton gradients across their plasma membranes
E)mitochondria,chloroplasts,and bacteria that generate proton gradients across their plasma membranes

A)the energy required to remove an electron from a hydrogen atom
B)the energy provided by a transmembrane hydrogen ion gradient
C)the energy that moves hydrogen into the intermembrane space
D)the energy that moves hydrogen atoms into the mitochondrion

A)carbon dioxide (CO₂)
B)glucose (C₆H₁₂O₆)
C)pyruvate (C₃H₃O₃^-)
D)molecular oxygen (O₂)

A)glucose
B)ethanol
C)pyruvate
D)lactic acid

A)2
B)6
C)14
D)28
E)60

A)glycolysis
B)fermentation
C)oxidation of pyruvate to acetyl CoA
D)citric acid cycle
E)oxidative phosphorylation (chemiosmosis)

A)energy released as electrons flow through the electron transport system
B)energy released from substrate-level phosphorylation
C)energy released from ATP hydrolysis
D)energy released from movement of protons down their electrochemical gradient through ATP synthase

A)cytosol
B)outer mitochondrial membrane
C)inner mitochondrial membrane
D)mitochondrial intermembrane space
E)mitochondrial matrix

A)to increase the rate of oxidative phosphorylation from its few mitochondria
B)to increase the metabolic rate when it is especially hot
C)to increase the rate of ATP production
D)to regulate temperature by converting most of the energy from the mitochondrial proton gradient to heat

A)ATP hydrolysis
B)redox reactions in the electron transport chain
C)decreasing the pH in the mitochondrial matrix
D)splitting water to form oxygen and protons

A)NADH → oxidative phosphorylation → ATP → oxygen
B)citric acid cycle → FADH₂ → electron transport chain → ATP
C)electron transport chain → citric acid cycle → ATP → oxygen
D)citric acid cycle → ATP → NADH → oxygen
E)citric acid cycle → NADH → electron transport chain → oxygen

A)2
B)4
C)8
D)30-32

A)the formation of ATP.
B)the reduction of NAD⁺.
C)a decrease in the pH of the mitochondrial matrix.
D)the creation of a proton-motive force.

A)conversion of potential energy to kinetic energy.
B)an endergonic reaction coupled to an exergonic reaction.
C)a redox reaction.
D)allosteric regulation.

A)mitochondrial matrix
B)electron transport chain
C)inner membrane
D)outer membrane

A)ATP synthase will increase the rate of ATP synthesis.
B)ATP synthase will synthesize ATP and pump protons into the intermembrane space.
C)ATP synthase will hydrolyze ATP and pump protons into the intermembrane space.
D)ATP synthase will hydrolyze ATP and pump protons into the matrix.

A)ATP synthesis and heat generation will both increase.
B)ATP synthesis will increase,and heat generation will decrease.
C)ATP synthesis will decrease,and heat generation will increase.
D)ATP synthesis and heat generation will both decrease.

A)the oxidation of pyruvate to acetyl CoA
B)the citric acid cycle
C)oxidative phosphorylation
D)glycolysis
E)fermentation

A)It is reduced and converted back to pyruvate in muscle cells.
B)It is oxidized to CO₂ and water.
C)It is taken to the liver and converted back to pyruvate.
D)It is converted to alcohol.

A)ATP,NADH,and pyruvate.
B)ATP and lactate.
C)ATP,CO₂,and lactate.
D)ATP,CO₂,and ethanol.
E)ATP,CO₂,and acetyl CoA.

A)only glycolysis and fermentation
B)only glycolysis and the citric acid cycle
C)only glycolysis and pyruvate oxidation
D)only oxidative phosphorylation,using an electron acceptor other than oxygen
E)glycolysis,pyruvate oxidation,the citric acid cycle,and oxidative phosphorylation,using an electron acceptor other than oxygen

A)the oxidation of pyruvate to acetyl CoA
B)the citric acid cycle
C)oxidative phosphorylation
D)glycolysis
E)chemiosmosis

A)Glycolysis is widespread and is found in the domains Bacteria,Archaea,and Eukarya.
B)Glycolysis neither uses nor requires O₂.
C)Glycolysis occurs in all eukaryotic cells.
D)The enzymes of glycolysis are localized in the cytosol rather than in a membrane-enclosed organelle.

A)the electron transport chain
B)substrate-level phosphorylation
C)chemiosmosis
D)oxidative phosphorylation
E)aerobic respiration

A)glycolysis and fermentation
B)fermentation and chemiosmosis
C)glycolysis and oxidation of pyruvate to acetyl CoA
D)oxidation of pyruvate to acetyl CoA and the citric acid cycle
E)fermentation and oxidative phosphorylation

A)glucose
B)proteins
C)fatty acids
D)pyruvate

A)lactate
B)glyceraldehyde-3-phosphate
C)oxaloacetate
D)acetyl CoA
E)citrate

A)as pyruvate
B)as glyceraldehyde 3-phosphate
C)as CO₂
D)as acetyl CoA
E)as glycerol

A)It produces much less ATP than does oxidative phosphorylation.
B)It does not involve organelles or specialized structures,does not require oxygen,and is present in most organisms.
C)It is found in prokaryotic cells but not in eukaryotic cells.
D)It relies on chemiosmosis,which is a metabolic mechanism present only in prokaryotic cells.

A)1
B)2
C)11
D)12
E)24

A)glycolysis and fermentation
B)fermentation and chemiosmosis
C)oxidation of pyruvate to acetyl CoA
D)citric acid cycle
E)oxidative phosphorylation

A)the oxidation of pyruvate to acetyl CoA
B)the citric acid cycle
C)chemiosmosis
D)the electron transport chain
E)glycolysis

A)breakdown of glucose
B)breakdown of pyruvate
C)breakdown of proteins
D)breakdown of fatty acids

A)oxidation of ethanol to acetaldehyde
B)oxidation of pyruvate to acetyl CoA
C)reduction of pyruvate to lactate
D)reduction of acetaldehyde to ethanol
E)reduction of acetyl CoA to ethanol

A)fats only
B)carbohydrates only
C)proteins only
D)fats,carbohydrates,and proteins
E)fats and proteins only

A)to reduce NAD⁺ to NADH
B)to reduce FAD⁺ to FADH₂
C)to oxidize NADH to NAD⁺
D)to oxidize FADH₂ to FAD

A)The mutant yeast will be unable to metabolize glucose.
B)The mutant yeast will be unable to grow anaerobically.
C)The mutant yeast will be unable to grow aerobically.
D)The mutant yeast will grow anaerobically only when provided glucose.